JP2017161216A - Air-conditioning controller, air-conditioning control method and program - Google Patents

Abstract

PROBLEM TO BE SOLVED: To automatically determine a period to be controlled without an instruction from a user, to control an air conditioner.SOLUTION: An air-conditioning controller 1 includes: a control period calculation unit 14 configured to calculate a control period of maintaining control to an air conditioner 4, based on control history on control to the air conditioner and operation history on operation to the air conditioner; and a control instruction unit 15 configured to instruct the air conditioner to maintain the control from starting control until the control period elapses.SELECTED DRAWING: Figure 1

Description

  Embodiments described herein relate generally to an air conditioning control device, an air conditioning control method, and a program.

  When using air conditioning in offices, etc., there is a possibility that comfort will be lost if aiming at energy saving, and conversely, there is a possibility that energy saving will not be achieved if aiming for comfort, and energy saving and comfort are in a trade-off relationship. It can be said. Therefore, an air conditioning control device that can obtain an energy saving effect while maintaining a level of comfort that can be accepted by an air conditioning user is desired.

  In order for the air conditioning control device to determine whether it is comfortable enough for the air conditioning user, it is necessary to make the air conditioning user declare the comfort and generate a criterion based on the result of the declaration. . However, there is a possibility that the user may be dissatisfied due to the trouble of filing, and there arises a problem that a function for accepting filing must be added.

Japanese Patent No. 4171006

  Embodiment of this invention controls an air conditioner so that a user's comfort may not be impaired, even if there is no report from a user.

  An air conditioning control device according to one aspect of the present invention includes a control period calculation unit that calculates a control period for maintaining control of the air conditioner based on a control history related to control of the air conditioner and an operation history related to operation of the air conditioner. And a control instruction unit that gives an instruction to the air conditioner to maintain the control until the control period elapses from the start of the control.

The block diagram which shows schematic structure of the air conditioning system which concerns on 1st Embodiment. The figure which shows an example of the information memorize | stored in a log | history memory | storage part. The figure which shows an example of the control rule memorize | stored in a control rule memory | storage part. The figure explaining calculation of a control period. The flowchart of the control processing of the air-conditioning control apparatus which concerns on 1st Embodiment. The flowchart of the update process of the control rule of the air-conditioning control apparatus which concerns on 1st Embodiment. The block diagram which shows schematic structure of the air conditioning system which concerns on 2nd Embodiment. The flowchart of the update process of the control rule of the air-conditioning control apparatus which concerns on 2nd Embodiment. The block diagram which shows schematic structure of the air conditioning system which concerns on 3rd Embodiment. The figure which shows an example of the environmental information memorize | stored in an environmental history memory | storage part. The block diagram which shows schematic structure of the air conditioning system which concerns on 4th Embodiment. The figure which shows another example of the environmental information memorize | stored in an environmental history memory | storage part. The figure explaining the method of evaluating energy saving property. The flowchart of the update process of the control rule of the air-conditioning control apparatus which concerns on 4th Embodiment. The image figure of an air-conditioning control system. The block diagram which shows schematic structure of the air conditioning system which concerns on 5th Embodiment. The figure explaining the data used for calculation of a control period. The figure which shows an example of the control rule memorize | stored in a control rule memory | storage part. The flowchart of the control processing of the air-conditioning control apparatus which concerns on 5th Embodiment. The flowchart of the update process of the control rule of the air-conditioning control apparatus which concerns on 5th Embodiment. The block diagram which shows an example of the hardware constitutions which implement | achieved the air-conditioning control apparatus which concerns on one Embodiment of this invention.

An air conditioning control device according to one aspect of the present invention includes a control period calculation unit that calculates a control period for maintaining control of the air conditioner based on a control history related to control of the air conditioner and an operation history related to operation of the air conditioner. And a control instruction unit that gives an instruction to the air conditioner to maintain the control until the control period elapses from the start of the control.
Embodiment of this invention controls an air conditioner so that a user's comfort may not be impaired, even if there is no report from a user.
Hereinafter, embodiments of the present invention will be described with reference to the drawings.

(First embodiment)
FIG. 1 is a block diagram showing a schematic configuration of the air conditioning system according to the first embodiment. The air conditioning system in the first embodiment includes an air conditioning control device 1, an input / output device 2, an instruction receiving device 3, and an air conditioning device 4.

  The air conditioning control device 1 includes a history acquisition unit 11, a history storage unit 12, a control rule storage unit 13, a control period calculation unit 14, and a control instruction unit 15.

  The air conditioning control device 1 controls the air conditioning device 4. However, the period during which the air conditioning control device 1 controls the air conditioning device 4 is limited. For example, when the air conditioner 4 is cooling, if the air conditioner control device 1 performs stop control, the air conditioner 4 stops for a certain period, but after a certain period, the control is canceled, and the air conditioner 4 Cool again. Here, a certain period during which the control of the air conditioner 4 is maintained is referred to as a control period. The air conditioning control device 1 automatically calculates this control period without using reporting data from the user of the air conditioning device 4. Note that the control may be canceled by a user operation or the like during the control period. Details will be described later.

  The input / output device 2 includes an input unit 21 that receives an instruction to the air conditioner 4 and gives the instruction to the air conditioner 4 when operated by a user or the like. The air conditioner 4 performs an operation based on the instruction. The input unit 21 may receive an instruction to the air conditioning control device 1 and give the instruction to the air conditioning control device 1. For example, the input unit 21 can update the permission and non-permission of the control rule stored in the control rule storage unit 13 by being operated by a user or the like. The input / output device 2 may include a display unit 22 that displays information such as the state of the air conditioning control device 1 or the air conditioning device 4.

  The input / output device 2 may be, for example, a remote controller of the air conditioner 4 or a general-purpose computer such as a smartphone, a tablet, or a PC having a keyboard, a mouse, a touch panel, a switch, or a display. . The input / output device 2 may be included in the air conditioner 4.

  The instruction receiving device 3 receives an instruction from another device and operates the air conditioner 4 according to the instruction. In FIG. 1, the instruction receiving device 3 is shown outside the air conditioner 4, but may be inside the air conditioner 4, or may be inside the air conditioner control device 1 or the input / output device 2.

  The air conditioner 4 changes the operating state based on an instruction from the instruction receiving device 3. There are various operating states of the air conditioner 4 such as cooling, heating, air blowing, dehumidification, and stopping, but are not particularly limited.

  Here, the predetermined space as a target is simply referred to as a room, the inside of the space is referred to as an indoor, and the outside of the space is referred to as an outdoor. However, the target predetermined space is not limited to one area in the building, and may be the entire building or the entire floor of the building.

  The air conditioner 4 is an air conditioner for buildings, for example, and includes an outdoor unit 41 that performs heat exchange between the heat medium and outdoor air, and an indoor unit that performs heat exchange between the heat medium and indoor air. It is assumed that the indoor unit 42 that adjusts the temperature is provided, but the configuration is not particularly limited. Further, the air conditioner 4 may have an internal sensor 43 that measures the temperature inside or near the air conditioner 4.

  The air conditioner 4 or the air conditioner control apparatus 1 performs feedback control based on information measured by the internal sensor 43 of the air conditioner 4 or an external sensor (not shown) after an instruction to the air conditioner 4 is given. May be provided. For example, when a predetermined period has elapsed since the air conditioner 4 received the instruction, it may be determined whether the instruction has been achieved and the instruction may be continued.

  Next, the internal configuration of the air conditioning control device 1 will be described.

  The history acquisition unit 11 acquires a history regarding an instruction (operation) given from the input / output device 2 to the air conditioner 4. Here, this history is referred to as an operation history. The operation history is used for calculation of the control period performed by the control period calculation unit 14.

  The operation history is acquired from the input / output device 2. When the instruction receiving device 3 or the air conditioner 4 can recognize that the instruction is from the input / output device 2, an operation history may be acquired from the instruction receiving device 3 or the air conditioner 4.

  The history acquisition unit 11 may dynamically make an inquiry to acquire an operation history or wait for an operation history to be sent.

  Moreover, the history acquisition unit 11 may acquire a history related to room temperature. Here, this history is referred to as room temperature history. The room temperature history is used to determine whether or not the control instruction unit 15 instructs control.

  The room temperature history is recorded by the internal sensor 43 of the air conditioner 4, and the history acquisition unit 11 acquires it from the air conditioner 4. Alternatively, the room temperature history may be recorded by an external sensor (not shown), and the history acquisition unit 11 may acquire from the external sensor.

  Further, the history acquisition unit 11 may acquire a history regarding the operating state of the air conditioner 4 from the air conditioner 4. Here, this history is referred to as an operation history.

  The history storage unit 12 stores an operation history and a control history. The control history means a history related to an instruction (control) given from the air conditioning control device 1 to the air conditioning device 4. The control history is used for calculation of the control period performed by the control period calculation unit 14. Further, a room temperature history and an operation history may be stored.

  FIG. 2 is a diagram illustrating an example of information stored in the history storage unit 12. In the example of FIG. 2, the operation history, the control history, the room temperature history, and the operation history are merged. As described above, the history storage unit 12 may merge and store the histories in one table, or may store the histories separately.

  The date and time in the first column indicates the date and time when the history was recorded. The operation state of the air conditioner 4 is shown in the operation state of the second row. For example, “cooling” means that the air conditioner 4 is cooling. “Stopped” means that the air conditioner 4 is in a stopped state. The stopped state may be a state where the power supply of the air conditioner 4 is stopped, or may be a power saving state.

  The set temperature in the third column indicates the set temperature of the air conditioner 4. The room temperature in the fourth row indicates the room temperature.

  The input destination in the fifth column indicates that the operation state of the air conditioner 4 has changed in response to an instruction from the air conditioner control device 1 or the input / output device 2 to the air conditioner 4. “System” indicates an instruction from the air conditioning control device 1. Therefore, it can be seen that the change in the operation state from the cooling to the stop shown in the third line from the top is due to the control of the air conditioning control device 1. The information shown in the third line from the top can be said to be a control history.

  “User” indicates an instruction from the input device. Therefore, it can be seen that the operation of cooling the state shown in the seventh line from the top is due to the user operating the input / output device 2 or the like. The information shown on the seventh line from the top can be said to be an operation history.

  The line in which neither the system nor the user is recorded is not a record from the air conditioning control device 1 or the input / output device 2 to the air conditioning device 4, but is a history recorded by the air conditioning device 4 periodically. The information shown in these lines can be said to be an operation history.

  In FIG. 2, since the operation state of the air conditioner 4 is recorded in all rows, it can be said that all rows are operation histories. Further, since room temperature is recorded in all rows, it can be said that all rows are room temperature history. The room temperature may be calculated based on a plurality of values measured by a plurality of sensors. For example, one of the plurality of values may be recorded, or an average value of the plurality of values may be recorded. The same applies to the room temperature described below.

  The history storage unit 12 acquires and stores a control history from the control instruction unit 15 that sends an instruction to the air conditioner 4. When the instruction receiving device 3 or the air conditioning device 4 can recognize that the instruction is from the air conditioning control device 1, the operation history is received from the instruction receiving device 3 or the air conditioning device 4 via the history acquisition unit 11. You may get it.

  The control rule storage unit 13 stores information related to the control for the air conditioner 4. Here, information regarding control is referred to as a control rule. It is assumed that the control rule is stored in advance in the control rule storage unit 13. One or more control rules may be used.

  FIG. 3 is a diagram illustrating an example of the control rules stored in the control rule storage unit 13. Each row of the table in FIG. 3 represents one control rule. The control rule shown in FIG. 3 relates to cooling, and the control rule is divided for each set temperature before control.

  A control condition (applicable condition) including an operation state before control in the first row and a set temperature before control in the second row indicates a condition for applying the control. The set temperature before the control is a value when the room temperature is stable. For example, the control rule in the third line from the top is applied when the operating state before control is cooling and the room temperature before control is stable. The temperature stability means that the temperature change is within a certain range in a predetermined period. For example, if the temperature change is between 26.5 ° C. and 27.4 ° C. in a fixed period of 5 minutes, it is considered stable at 27 ° C.

  The control contents in the third to fifth columns mean the contents of control performed when the control condition is satisfied. Note that the control content here is reduction of power consumption (power consumption) of the air conditioner 4, that is, control for energy saving. For example, there is a stop, a decrease in the set temperature during heating, an increase in the set temperature during cooling, and a change to the air blowing mode during cooling. Since air blowing consumes less power than cooling, it is assumed that an energy saving effect is obtained by switching the operating state from cooling to blowing.

  The operation state after the control in the third row indicates the operation state of the air conditioner 4 changed by the control. The set temperature after control in the fourth column indicates the set temperature set by the control. In the control rule on the sixth line from the top, it is assumed that the operating state is cooling, but the set temperature is changed to 26 ° C. As a result, the set temperature becomes higher than the set temperature (25 ° C.) before the control, thereby saving power.

  The control period in the fifth column means a control period corresponding to the control rule. For example, in the control rule on the third line from the top, the time that the air conditioner 4 continues to stop is 10 minutes. As described above, when a control rule in which a control period is defined is applied, the control content is maintained until the control period elapses from the start of control. However, when the user operates the air conditioner 4 during the control period, the control is released. It is assumed that after the stop time, the air conditioner 4 returns to the original state. That is, if it is a control rule shown in FIG. 3, it will return to the cooling state which is the driving | running state before control. In order to return to the cooling state, when the control period elapses, the control instruction unit 15 may give an instruction to return to the operation state before the control to the air conditioner 4 again. Or the instruction | indication reception apparatus 3 or the air conditioner 4 may memorize | store a control period, and may return to the operating state before control automatically after control period progress.

  Control permission in the sixth column determines whether or not the control rule can be executed. The permitted control rule is executed, but the non-permitted control rule is not executed.

  The control period calculation unit 14 calculates the control period of the control rule based on the control history and the operation history stored in the history storage unit 12. In addition, the control period calculation unit 14 updates the control rule stored in the control rule storage unit 13 with the calculated control period.

The calculation of the control period will be described. FIG. 4 is a diagram illustrating calculation of the control period. FIG. 4A is a diagram illustrating the survival time of each control rule calculated by the control period calculation unit 14.
For example, as shown in FIG. 2, it is assumed that the air conditioning control device 1 stops the cooling at 10:40 and the user operates the cooling at 11:00. When the control period calculation unit 14 detects the control by the air conditioning control device 1 performed at 10:40 from the control history of the history storage unit 12, the control period calculation unit 14 performs control by the air conditioning control device 1 as shown in FIG. Start date and time and control rules (control conditions and control contents in FIG. 4) are extracted. Then, an operation by the user performed at 11:00 is detected from the operation history of the history storage unit 12, and it is determined that the control by the air conditioning control device 1 has been completed, and the start date and time of the operation by the user is acquired. Based on the start date and time of control by the air conditioning control device 1 and the start date and time of operation by the user, the survival time of the control by the air conditioning control device 1 is calculated as 20 minutes.

  FIG. 4B is a diagram showing the relationship between the control time and the survival time in the above example. Although the stop state of the air conditioner 4 was scheduled to be maintained in the control period from the start of control to the scheduled control end, the air conditioner 4 is in the cooling state after the operation. That is, as shown in FIG. 4B, the survival time is a time from the start of control until the control is not maintained by an operation or the like, and means a time when the control by the air-conditioning control device 1 actually continues. In this way, the survival time of each control by the air conditioning control device 1 is calculated and recorded as shown in FIG.

  The control period calculation unit 14 may determine whether to use the survival time as a sample after calculating the survival time. For example, a sample that can be determined to have a long survival time, such as 60 minutes or more, may not be used as a sample because there is a high possibility that the user has left the room. A criterion for determining whether or not to use the calculated survival time as a sample may be arbitrarily determined.

  FIG. 4C is a diagram showing an approximate graph of a survival rate function for calculating a control period from a plurality of calculated survival time samples. First, the control period calculation unit 14 calculates a survival rate function from the sample data of the survival time shown in FIG. The survival rate function indicates a survival rate that is a probability that the control is alive (continuous) at a certain time. The survival rate function can be calculated using, for example, Kaplan-Meier estimation method, Weibull distribution, or the like. And the control period calculation part 14 calculates the time when a survival rate becomes below a predetermined threshold value (s0 in FIG. 4) as a control period. In this way, the control period for each control rule is calculated.

  Here, it is assumed that a plurality of survival times are calculated for each control rule, and a control period is calculated from the survival time, but based on a plurality of survival times calculated for each element or combination of elements of the control rule. Thus, the control period may be calculated. The elements of the control rule are elements of the control condition and elements of the control content, such as an operating state before control, a set temperature before control, an operating state after control, a set temperature after control, and the like.

  The control instruction unit 15 gives an instruction based on the control rule to the air conditioner 4 via the instruction receiving device 3. For example, the instruction based on the control rule shown in the third line of FIG. 3 is an instruction to maintain the stop state as the control content until 10 minutes of the control period elapses from the start of the control. The control instruction unit 15 checks whether or not the control rule of the control rule stored in the control rule storage unit 13 is satisfied. If the control condition is satisfied, the control instruction unit 15 gives an instruction based on the control content of the control rule.

  The control instruction unit 15 may determine whether or not the control condition is satisfied based on the room temperature history in the history storage unit 12. The confirmation as to whether or not the control condition is satisfied may be periodically performed, or may be performed, for example, when it is notified from the history storage unit 12 that a room temperature history has been added.

  Further, when giving an instruction to the instruction receiving device 3, the control instruction unit 15 notifies the history storage unit 12 of the content of the instruction, and the history storage unit 12 stores it as a control history.

  Next, the process flow of the air conditioning control device 1 according to the present embodiment will be described. FIG. 5 is a flowchart of the control processing of the air conditioning control device 1 according to the first embodiment. It is assumed that this flow starts when power is turned on or an instruction from a user or the like is received. In addition, it is assumed that necessary information is already stored in the history storage unit 12 and the control rule storage unit 13.

  The control instruction unit 15 refers to the room temperature history in the history storage unit 12 and determines whether the room temperature has stabilized (S101). When the control instruction unit 15 determines that the room temperature is not stable (NO in S102), the control instruction unit 15 waits until the next determination opportunity and performs determination again. The next determination opportunity may be a predetermined timing, or may be when the update of the room temperature history is notified from the history acquisition unit 11. If the control instruction unit 15 determines that the room temperature is stable (YES in S102), the control instruction unit 15 refers to the control rule storage unit 13 and extracts a control rule that matches the control condition of each control rule (S103).

  When the control permission item of the extracted control rule is not permitted (NO in S104), this flow ends. When the control permission item of the extracted control rule is permission (YES in S104), the control instruction unit 15 gives an instruction based on the control content of the control rule to the instruction receiving device 3 (S105). Thereby, the instruction receiving device 3 controls the air conditioner 4.

  In addition, the flowchart demonstrated here is an example, and is not restricted to this. Other processing may be included. The same applies to the flowcharts described below.

  FIG. 6 is a flowchart of control rule update processing of the air conditioning control device 1 according to the first embodiment. It is assumed that this flow is started in response to a predetermined timing or an instruction from a user or the like. In addition, it is assumed that necessary information is already stored in the history storage unit 12 and the control rule storage unit 13.

  The control period calculation unit 14 detects the control history and the operation history stored in the history storage unit 12, and calculates the survival time for each control rule of the air conditioning control device 1 (S201). Then, processing for updating the control period (S202 to S205) is performed for each control rule.

  First, the control period calculation unit 14 confirms whether the sample data (calculated survival time) corresponding to the control rule is a sufficient amount (S202). If the sample data is not a sufficient amount (NO in S203), the process proceeds to the next control rule. When the sample data is a sufficient amount (YES in S203), the control period calculation unit 14 generates a survival rate function from the sample data, and calculates the control period based on a predetermined threshold (S204). The control period calculation unit 14 sends the calculated control period to the control rule storage unit 13, and the control rule storage unit 13 updates the control period of the corresponding control rule (S205). Then, the control period calculation unit 14 proceeds to the processing of the next control rule. When the processing is completed for all the control rules, this flow ends.

  Here, the survival time is calculated for each control rule. However, as described above, the survival time may be calculated for each element of the control rule.

  As described above, according to the first embodiment, an appropriate control period can be obtained from how the air conditioner 4 is used without using a report from the user. Thereby, the air conditioner 4 can be controlled to save power while reducing user dissatisfaction with the control.

(Second Embodiment)
In the second embodiment, the air conditioning control device 1 updates the value of the control permission item of the control rule shown in FIG. 3 to prevent the user from applying a control rule that is uncomfortable for the user.

  FIG. 7 is a block diagram illustrating a schematic configuration of an air conditioning system according to the second embodiment. The air conditioning control device 1 according to the second embodiment differs from the first embodiment in that it further includes a comfort evaluation unit 16. The description of the same parts and processes as those in the first embodiment will be omitted.

  The comfort evaluation unit 16 evaluates whether the applied control rule is comfortable or uncomfortable for the user (comfort) based on the user's operation. In the control rule determined to be uncomfortable, the control permission item of the control rule stored in the control rule storage unit 13 is updated from permission to disapproval, and the control rule is not instructed by the control instruction unit. This reduces user dissatisfaction with the control.

  For example, the control is performed so that the user cools the air conditioner 4 via the input / output device 2 after the air conditioner 4 stops cooling by the control of the air conditioner control apparatus 1 until a predetermined period of time elapses. Consider the case. In such a case, it is assumed that a situation where the control of the air conditioning control device 1 is interrupted by the user has occurred, and it is estimated that the control rule is uncomfortable for the user. Thus, if the situation where the control of the air-conditioning control apparatus 1 is interrupted frequently by the user occurs, it is considered that the control rule should not be applied.

  The predetermined fixed period may be arbitrarily determined as long as it is equal to or shorter than the control period. Here, the predetermined fixed period is referred to as an evaluation determination period.

  First, the comfort evaluation unit 16 interrupts the control from the input / output device 2 from the control history and operation history of the history storage unit 12 until the evaluation judgment period elapses after the control of the air conditioning control device 1. Check if something happened. Then, in the evaluation determination period, when the number of times that a situation in which control by a certain control rule is interrupted by the user is equal to or greater than a predetermined threshold, the control rule is determined as an unpleasant control rule.

  And the comfort evaluation part 16 updates the control permission item of the control rule judged to be uncomfortable memorize | stored in the control rule memory | storage part 13 to disapproval. Thereby, even when the control condition of the control rule is satisfied after the update, the control rule is not applied. In addition, the comfort evaluation part 16 may change the rule changed into non-permission to permit, when fixed time passes after updating to non-permission.

  Next, the flow of comfort evaluation processing will be described. FIG. 8 is a flowchart of control rule update processing of the air-conditioning control apparatus 1 according to the second embodiment. Here, it is assumed that the comfort evaluation process is performed as one of the update processes of the control rule. The comfort evaluation process may be performed separately from the control rule update process.

  The processing from S201 to S205 is the same as in the first embodiment. After the process of S205, the comfort evaluation unit 16 refers to the control history and operation history of the history storage unit 12, and measures the number of times control is interrupted by the user within the evaluation determination period (S301). If the number of interruptions is less than the threshold (NO in S302), the process proceeds to the next control rule. If the number of interruptions is equal to or greater than the threshold (YES in S302), the control permission item of the control rule stored in the control rule storage unit 13 is updated to disallowed. Then, the process proceeds to the next control rule, and when the process is completed for all the control rules, this flow ends.

  In the above flow, processing is performed for all target control rules, but before S301, the control permission item of the control rule is confirmed, and the control rules that are not permitted are processed from S301 to S303. You may not do it.

  As described above, according to the second embodiment, it is possible to determine whether the control is comfortable or uncomfortable from how the air conditioner 4 is used without using a report from the user. Then, the control based on the control rule determined to be uncomfortable may not be performed. Thereby, the dissatisfaction of the user with respect to control can be reduced.

(Third embodiment)
In the third embodiment, the control period is calculated based on the environment around the air conditioner 4. FIG. 9 is a block diagram illustrating a schematic configuration of an air conditioning system according to the third embodiment. The air conditioning system according to the third embodiment differs from the first and second embodiments in that an external sensor 5 is included. The air conditioning control device 1 according to the third embodiment is different from the first and second embodiments in that it further includes an environment information acquisition unit 17 and an environment history storage unit 18. The description of the same parts and processes as those in the first and second embodiments is omitted.

  The environment information acquisition unit 17 acquires environment information related to the environment around the air conditioner 4. The periphery may be indoors or outdoors. The environment history storage unit 18 stores the acquired environment information. FIG. 10 is a diagram illustrating an example of environment information stored in the environment history storage unit 18. The measured date and time, the attribute, and the value of the attribute are shown. The attribute is not particularly limited as long as it represents the environment around the air conditioner 4, and includes, for example, room temperature, outside air temperature (outdoor temperature), rainfall, humidity, and wind speed.

  Here, it is assumed that the environmental information is measured by the external sensor 5 and transmitted from the external sensor 5 to the environmental information acquisition unit 17. However, the environment information acquisition unit 17 may acquire the environment information from a server or a cloud service that provides the environment information instead of from the external sensor 5, and the acquisition destination of the environment information may be arbitrarily determined.

  Further, the environmental information may be predicted information instead of actually measured information. For example, it may be weather prediction information provided by the Japan Meteorological Agency or the like.

  It is assumed that the environmental information is used when the control period calculation unit 14 calculates the control period. The control period calculation unit 14 may calculate the control period of control performed in the environmental state based on the survival time calculated for each environmental state indicated by the attribute of the environmental information or a combination thereof.

  When the internal sensor 43 of the air conditioner 4 can acquire environmental information, the environmental information acquired by the internal sensor 43 may be used.

  In addition, since the flow of the update process of the control rule of the air-conditioning control apparatus 1 which concerns on 3rd Embodiment is the same as that of the 1st or 2nd embodiment, it abbreviate | omits.

  As described above, according to the third embodiment, by calculating the control period using the environment information, the control period can be set to a value according to the situation. Thereby, the dissatisfaction of the user with respect to control can be reduced more.

(Fourth embodiment)
The fourth embodiment evaluates the energy saving performance of the control rule, updates the value of the control permission item of the control rule based on the evaluation result, and prevents a control rule that does not save energy from being applied.

  FIG. 11 is a block diagram illustrating a schematic configuration of an air conditioning system according to the fourth embodiment. The air-conditioning control apparatus 1 according to the fourth embodiment differs from the first to third embodiments in that it further includes an energy saving evaluation unit 19. The description of the same parts and processes as those in the first to third embodiments is omitted.

  Even if the air-conditioning control device 1 controls the air-conditioning device 4, it does not necessarily save power. Therefore, the energy saving evaluation unit 19 compares the power consumption of the air conditioner 4 when the control is not applied with the power consumption of the air conditioner 4 when the control is applied, and evaluates the energy saving.

  The power consumption may be measured by the internal sensor 43 or the external sensor 5 of the air conditioner 4. Further, the power consumption may be predicted from the measured room temperature, the size of the target space, the specific heat, and the like, instead of directly measuring the power consumption. Here, the history regarding power consumption is referred to as power consumption history.

  FIG. 12 is a diagram illustrating another example of the environment information stored in the environment history storage unit 18. In the fourth and seventh lines from the top, the power consumption acquired by the external sensor 5 is shown. Therefore, the information shown in the fourth and seventh lines from the top can be said to be a power consumption history. Thus, the power consumption acquired by the internal sensor 43 or the external sensor 5 of the air conditioner 4 is stored in the history storage unit 12 or the environment history storage unit 18.

  FIG. 13 is a diagram illustrating a method for evaluating energy saving performance. The graph in FIG. 13A shows the power consumption of the air conditioner 4 when the control rule is applied. Since there is a control period, a period during which the air conditioner 4 is controlled (a period during which the air conditioner 4 stops in FIG. 13) and a period during which the air conditioner 4 is not controlled (a period during which the air conditioner 4 cools in FIG. 13) are repeated. The graph in FIG. 13A is up and down.

  The graphs of FIGS. 13B and 13C show the power consumption of the air conditioner 4 when the control rule is not applied and the room temperature is stable. FIG. 13B shows power consumption of the air conditioner 4 in which the inverter is mounted. FIG. 13C shows power consumption of the air conditioner 4 in which no inverter is mounted.

  The power consumption of the air conditioner 4 in which the inverter is mounted is stable as shown in FIG. 13B when the room temperature is stable. On the other hand, the power consumption of the air conditioner 4 on which the inverter is not mounted rises and falls as shown in FIG. 13C even when the room temperature is stable. This is because the air conditioner 4 in which the inverter is not mounted is intermittently operated alternately between a period during which cold air is emitted and a period during which the cold air is not emitted even when the room temperature is stabilized.

  The power saving effect depends on the average power consumption W1 per unit time when the control rule is applied, and the average power consumption per unit time when the control rule is not applied and the room temperature is stable It can be confirmed by comparing with the power W2.

  The average power consumption W1 is the power consumption W3 per unit time at the time of stoppage, the control period T3, the total power consumption E1 from the start of cooling until the room temperature becomes stable, and from the stop (start of control) until the room temperature becomes stable. By this period T1, W1 = {W3 × T3 + E1} / T1.

  Since the average power consumption W2 is stable when an inverter is mounted on the air conditioner 4, the power consumption per unit time when the room temperature is stable may be extracted from the power consumption history. When the inverter is not mounted on the air conditioner 4, the average power consumption W2 is the product of the power consumption W4 per unit time at the time of stoppage and the stop time T4, and the power consumption from the start of cooling until the room temperature becomes stable By the total E2 and the period T2 from the stop until the room temperature becomes stable, W2 = {W4 × T4 + E2} / T2.

  If the average power consumption W1 is greater than the average power consumption W2, the energy saving evaluation unit 19 determines that there is an energy saving effect. When the energy saving evaluation unit 19 determines that the energy is saved, the control permission item of the control rule is permitted, and when it is determined that there is no energy saving effect, the control permission item of the control rule is not permitted. Thereby, the control rule which does not become energy saving is not instruct | indicated from a control instruction | indication part, and the reliability of the energy saving effect by the air-conditioning control apparatus 1 increases.

  In the above description, it is assumed that the power consumption history of the air conditioning control device 1 is used. However, the power consumption history of other air conditioning devices 4 having similar types of the air conditioning devices 4 and the size of the room may be used. Good. Moreover, the said method is an example of the evaluation method of an energy saving effect, and an energy saving effect may be evaluated by another method.

  Next, the flow of the energy saving evaluation process will be described. FIG. 14 is a flowchart of control rule update processing of the air-conditioning control apparatus 1 according to the fourth embodiment. Here, it is assumed that an energy saving evaluation process is performed as one of the update processes of the control rule. The energy saving evaluation process may be performed separately from the update rule of the control rule. Further, when the comfort evaluation process is performed in the control rule update process, the energy saving evaluation process may be performed before or after the comfort evaluation process.

  The processing from S201 to S205 is the same as in the first embodiment. After the processing of S205, the energy saving evaluation unit 19 refers to the operation history of the history storage unit 12, calculates the average power consumption W1 and the average power consumption W2, and then determines whether there is an energy saving effect by the control ( S401). Then, the control permission item of the control rule stored in the control rule storage unit 13 is updated to permit when there is a power saving effect and to disapproved when there is no power saving effect (S402). Then, the process proceeds to the next control rule, and when the process is completed for all the control rules, this flow ends.

  In the above flow, processing is performed for all target control rules. However, before S401, the control permission item of the control rule is confirmed, and the control rule that is not permitted performs the processing of S401 and S402. You may not do it.

  As described above, according to the fourth embodiment, the presence or absence of the energy saving effect is determined, and the control rule having no energy saving effect is not applied. Thereby, the reliability of control can be improved.

(Fifth embodiment)
In the fifth embodiment, a criterion for stopping control by the air conditioning control device 1 is provided to maintain the comfort of a worker (user).

  FIG. 16 is a block diagram illustrating a schematic configuration of an air conditioning system according to the fifth embodiment. The air conditioning control device 1 according to the fifth embodiment is different from the first to fourth embodiments in that it further includes a cancellation criterion calculation unit 20. The description of the same parts and processes as those in the first to fourth embodiments is omitted.

  Even if the air-conditioning control device 1 controls the air-conditioning device 4 in accordance with the control rules, there is a possibility of performing an operation that impairs the comfort of the office worker, for example, the room temperature increases too much. Therefore, we will establish a standard for canceling control rules to maintain the comfort of the workers.

  The stop criterion calculation unit 20 calculates a stop criterion for determining stop of control for the air conditioner 4 based on at least one of the control history and the operation history. FIG. 17 is a diagram illustrating data used for calculation of the control period. FIG. 17 shows an example of information used to calculate a cancellation criterion. In the table of FIG. 17, two items of room temperature at the end of control and room temperature change before and after control are added to each control rule shown in FIG. The room temperature at the end of control indicates the room temperature of the room that was the control target when the control was completed. The room temperature change before and after the control indicates a difference before and after the control of the room temperature of the room to be controlled. These items are calculated based on at least one of the control history and the operation history in order to calculate the cancellation criterion. Note that the cancellation criterion may be calculated using environment information instead of the control history and the operation history. Although room temperature is described in FIG. 17, there may be an item relating to the outside air temperature or the like.

  Then, the cancellation criterion calculation unit 20 calculates statistics for a plurality of survival time samples calculated for calculating the control period. For example, the minimum value or average value of the room temperature at the end of control may be calculated. Alternatively, a minimum value or an average value of room temperature changes before and after the control may be calculated. Then, the cancellation criterion calculation unit 20 generates a cancellation criterion using these statistics as conditions.

  A method for calculating the cancellation criterion, that is, a calculation formula and a parameter may be determined in advance and stored in the control rule storage unit 13 or the like. Note that one or more cancellation criteria may be generated. In addition, a fixed threshold value may be provided as a cancellation criterion instead of a statistic. A plurality of cancellation criteria may be combined. That is, the control may be stopped when some of the plurality of stop criteria are satisfied, or the control may be stopped when all of the plurality of stop criteria are satisfied.

  FIG. 18 is a diagram illustrating an example of a control rule including a cancellation criterion stored in the control rule storage unit 13. In the case where the control rule in the first row of the table of FIG. 18 is applied, it is assumed that the stop criterion is satisfied when the room temperature reaches 30 ° C. or when the temperature rise exceeds 4 ° C.

  The control instruction unit 15 checks whether or not the control rule cancellation condition stored in the control rule storage unit 13 is satisfied. If the cancellation condition is satisfied, the control instruction unit 15 receives an instruction to cancel the control related to the control rule. The air conditioner 4 is given via the device 3.

  The control instruction unit 15 may determine whether or not the stop condition is satisfied based on the room temperature history in the history storage unit 12. At this time, the instantaneous value or the value for a certain period may be used to determine whether or not the cancellation criterion is satisfied. The confirmation as to whether or not the stop condition is satisfied may be performed periodically, or may be performed, for example, when it is notified from the history storage unit 12 that a room temperature history has been added.

  Next, the process flow of the air conditioning control device 1 according to the present embodiment will be described. FIG. 20 is a flowchart of the control processing of the air conditioning control device according to the fifth embodiment. The processing from S101 to S105 is the same as in the first embodiment. The control instruction unit 15 extracts a rule during the control period from the history storage unit 12 during the control period (S501). When the control instruction unit 15 determines that the rule satisfies the cancellation criterion (YES in S502), the control instruction unit 15 instructs the instruction receiving device 3 to stop the control. If it is determined that the rule does not satisfy the cancellation criteria (NO in S502), the flow ends.

  Next, the flow of the cancellation criterion calculation process will be described. FIG. 21 is a flowchart of control rule update processing of the air-conditioning control apparatus 1 according to the fifth embodiment. Here, it is assumed that the cancellation criterion calculation process is performed as one of the control rule update processes. The cancellation criterion calculation process may be performed separately from the update of the control rule. In addition, when the comfort evaluation process or the energy saving evaluation is performed in the control rule update process, the cancellation criterion calculation process may be performed before the comfort evaluation process or the energy saving evaluation or may be performed later. It may be broken.

  The processing from S201 to S205 is the same as in the first embodiment. After the process of S205, the cancellation criterion calculation unit 20 refers to the room temperature of the history storage unit 12 and calculates the cancellation criterion (S506). And the item of the cancellation | release criteria of the said control rule memorize | stored in the control rule memory | storage part 13 is updated (S507). Then, the process proceeds to the next control rule, and when the process is completed for all the control rules, this flow ends.

  In the above flow, processing is performed for all target control rules, but before S501, the control permission item of the control rule is confirmed, and the control rule that is not permitted performs the processing of S506 and S507. You may not do it.

  As described above, according to the fifth embodiment, the control stop criterion is provided, and the control is stopped when the environment changes. Thereby, the comfort of the worker can be maintained.

  The air-conditioning control device 1 in the embodiments so far only needs to be able to communicate with the air-conditioning device 4 and the like for transmitting necessary information. The communication may be performed via various communication networks such as a dedicated line, a WAN (Wide Area Network), a LAN (Local Area Network), and the Internet. The communication network may be a wired network, a wireless network, or a wired and wireless hybrid network.

  FIG. 15 is an image diagram of an air conditioning control system. The air conditioning control device 1 in the embodiments so far may be included in a building management system such as BEMS (Building Energy Management System) or HEMS (Home Energy Management System) that manages the entire building in which the air conditioning device 4 is installed. Good. Further, the building management system may exist in the same building or network as the air conditioner 4 like the building management system 61 inside the network of FIG. 15, or the building management system 62 outside the network of FIG. Thus, it may exist in another network connected to the external network 7 or the like.

  Further, like the air conditioning control cloud service 63 in FIG. 15, the air conditioning control device 1 may control the air conditioning device 4 as a cloud service that provides a function via the external network 7 or the like. Thus, the air-conditioning control apparatus 1 may be used as a BEMS (Building Energy Management System), a HEMS (Home Energy Management System), a cloud service, or the like.

  In addition, each process in the embodiment described above can be realized by software (program). Therefore, the air-conditioning control apparatus 1 in the embodiment described above can be realized, for example, by using a general-purpose computer device as basic hardware and causing a processor mounted on the computer device to execute a program.

  FIG. 16 is a block diagram illustrating an example of a hardware configuration that implements the air conditioning control device 1 according to an embodiment of the present invention. The air conditioning control device 1 includes a processor 81, a main storage device 82, an auxiliary storage device 83, a network interface 84, a device interface 85, an input device 86, and an output device 87, which are connected via a bus 88. 8 can be realized.

  The processor 81 reads out the program from the auxiliary storage device 83, expands it in the main storage device 82, and executes it, whereby the control period calculation unit 14, the control instruction unit 15, the comfort evaluation unit 16, and the energy saving evaluation unit 19. The function can be realized.

  The air conditioning control device 1 of the present embodiment may be realized by installing a program executed by the air conditioning control device 1 in a computer device in advance, or storing the program in a storage medium such as a CD-ROM, Or you may implement | achieve by distributing via a network and installing in a computer apparatus suitably.

  The network interface 84 is an interface for connecting to a communication network. Functions for communicating with other devices such as the history acquisition unit 11 and the environment information acquisition unit 17 may be realized by the network interface 84. Although only one network interface is shown here, a plurality of network interfaces may be installed. The type of communication network to be connected is not particularly limited.

  The device interface 85 is an interface connected to a device such as an external storage device (external storage medium) 9. The external storage device 9 may be an arbitrary recording medium or storage device such as an HDD, a CD-R, a CD-RW, a DVD-RAM, a DVD-R, or a SAN (Storage area network). The history storage unit 12, the control rule storage unit 13, and the environment history storage unit 18 may be connected to the device interface 85 as the external storage device 9.

  The input device 86 includes input devices such as a keyboard, a mouse, and a touch panel. An operation signal generated by operating the input device is output to the processor 81. The output device 87 includes a display such as an LCD (Liquid Crystal Display) and a CRT (Cathode Ray Tube). The input device 86 or the output device 87 may be connected to the device interface 85 from the outside. The input / output device 2 may be realized as the input device 86 and the output device 87.

  The main storage device 82 is a memory device that temporarily stores instructions executed by the processor 81, various data, and the like, and may be a volatile memory such as a DRAM or a non-volatile memory such as an MRAM. The auxiliary storage device 83 is a storage device that permanently stores programs, data, and the like, such as an HDD or an SSD. Data stored in the history storage unit 12, the control rule storage unit 13, the environment history storage unit 18, and the like is stored in the main storage device 82, the auxiliary storage device 83, or the external storage device 9.

  Although one embodiment of the present invention has been described above, these embodiment are presented as examples and are not intended to limit the scope of the invention. These novel embodiments can be implemented in various other forms, and various omissions, replacements, and changes can be made without departing from the scope of the invention. These embodiments and modifications thereof are included in the scope and gist of the invention, and are included in the invention described in the claims and the equivalents thereof.

DESCRIPTION OF SYMBOLS 1 Air-conditioning control apparatus 11 History acquisition part 12 History storage part 13 Control rule memory | storage part 14 Control period calculation part 15 Control instruction | indication part 16 Comfort evaluation part 17 Environmental information acquisition part 18 Environmental history storage part 19 Energy-saving evaluation part 20 Cancellation criteria calculation Unit 2 Input / output device 21 Input unit 22 Display unit 3 Instruction receiving device 4 Air conditioner 41 Outdoor unit 42 Indoor unit 43 Internal sensor 5 External sensor 61 Building management system (BEMS / HEMS) inside the network
62 Building management system outside the network (BEMS / HEMS)
63 Air conditioning control cloud service 7 External network 8 Computer device 81 Processor 82 Main storage device 83 Auxiliary storage device 84 Network interface 85 Device interface 86 Input device 87 Output device 88 Bus 9 External storage device (external storage medium)

Claims (12)

A control period calculation unit that calculates a control period in which the control is maintained, based on a control history regarding control on the air conditioner and an operation history regarding operation on the air conditioner;
A control instruction unit that gives an instruction to the air conditioner to maintain the control until the control period elapses from the start of the control;
An air conditioning control device. The control period calculation unit calculates a survival time of the control based on the control history and the operation history and indicates a time from the start of the control until the control is not maintained by the operation, and the survival time The air-conditioning control apparatus according to claim 1, wherein the control period is calculated based on the air conditioner. A history storage unit for storing the control history and the operation history;
A control rule storage unit that stores the application condition of the control and the control period;
Further comprising
The control period calculation unit updates the control period stored in the control rule storage unit to the calculated new control period,
The air conditioning control device according to claim 1, wherein the control instruction unit gives the instruction to the air conditioning device when the application condition is satisfied. The control instruction unit gives the instruction to the air conditioner when a temperature of a space to be air-conditioned by the air conditioner falls within a predetermined first range in a predetermined first period. The air-conditioning control apparatus as described in any one of thru | or 3. A comfort evaluation unit that evaluates the comfort of the control based on the control history and the operation history;
The air conditioning control device according to any one of claims 1 to 4, wherein the control instruction unit does not give the instruction to the air conditioning device when the control is evaluated as uncomfortable by the comfort evaluation unit. The comfort evaluation unit makes the control uncomfortable when the number of times the control is interrupted by the operation exceeds a predetermined threshold before the predetermined second period is exceeded after the control is started. The air conditioning control device according to claim 5. An environmental information acquisition unit that acquires environmental information about the environment around the air conditioner;
An environment history storage unit for storing the environment information;
Further comprising
The control period calculation unit acquires the survival time in a predetermined environmental state based on the environmental information, the control history, and the operation history, and calculates the control period of the control performed in the predetermined environmental state. The air conditioning control device according to any one of claims 3 to 6, which is dependent on claim 2 or claim 2. An energy-saving evaluation unit that determines whether there is an energy-saving effect of the control based on the power consumption of the air-conditioning apparatus when the control is not applied and the power consumption of the air-conditioning apparatus when the control is applied Prepared,
The air conditioning control according to any one of claims 1 to 7, wherein the control instruction unit does not give the instruction to the air conditioner when the control is determined to have no energy saving effect in the energy saving evaluation unit. apparatus. A cancellation criterion calculating unit that calculates a cancellation criterion for determining whether to stop the control based on at least one of the control history and the operation history;
The said control instruction | indication part gives the instruction | indication of the stop of the said control to the said air conditioner, when it is judged that the said cancellation criteria are satisfy | filled during control of the said air conditioner. Air conditioning control device. A cancellation criterion calculating unit that calculates a cancellation criterion for determining whether to stop the control based on at least the environmental information;
The control instruction unit gives an instruction to stop the control to the air conditioner when it is determined that the stop criterion is satisfied during the control of the air conditioner. The air conditioning control device described in 1. A control period calculating step for calculating a control period in which the control is maintained based on a control history related to control of the air conditioner and an operation history related to operation of the air conditioner;
A control instruction step for giving an instruction to the air conditioner to maintain the control until the control period elapses from the start of the control;
The air conditioning control method that the computer executes. A control period calculating step for calculating a control period in which the control is maintained based on a control history related to control of the air conditioner and an operation history related to operation of the air conditioner;
A control instruction step for giving an instruction to the air conditioner to maintain the control until the control period elapses from the start of the control;
A program that causes a computer to execute.

Images